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NASA/TM--1999-209876
Friction Stir Welding for Aluminum
Metal Matrix Composites (MMC's)(MSFC Center Director's Discretionary Fund Final Report,Project No. 98-09)
J.A. Lee, R.W. Carter, and J. Ding
Marshall Space Flight Center, Marshall Space Flight Center, Alabama
December 1999
https://ntrs.nasa.gov/search.jsp?R=20000004679 2018-05-26T16:01:53+00:00Z
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NASA / TM--1999-209876
Friction Stir Welding for Aluminum
Metal Matrix Composites (MMC's)(MSFC Center Director's Discretionary Fund Final Report,Project No. 98-09)
J.A. Lee, R.W. Carter, and J. Ding
Marshall Space Flight Center, Marshall Space Flight Center, Alabama
National Aeronautics and
Space Administration
Marshall Space Flight Center • MSFC, Alabama 35812
December 1999
Acknowledgments
The Principal Investigator, Jonathan Lee, wishes to thank Robert Carter and Jeff Ding for their assistance in performing the
fiiction slir welding. Furthermore, the authors would like to acknowledge the financial support fiom the Center Director's
Discretionary Fund (CDDF) program officc at MSFC and to Mark van dcn Bcrgh, fi'om DWA Aluminum Composites, Inc.,for supplying mosl of thc composite matcrial panels used in this study.
Available fl'om:
NASA Center fl_l"AcroSpacc Information7121 Standard Drive
Hanover, MD 21076-1320
(301) 621-0390
National Technical Information Service
5285 Port Royal Road
Springficld, VA 22161(703) 487-4650
TABLE OF CONTENTS
i. INTRODUCTION ......."'''°''°°'''''°° ........ ''°'.*... °°°°.°°....°°°.Hi°, ..... °... ...... . .... °. .... ...°°..o°.°°°°°. .... ° .... °. ........
2. POTENTIAL ISSUES IN JOINING MMC'S............. ...°., ................ °°.... .... .° .... ° ..... ,,.°o_o........°. °....
2.1 Solidification Effects......... . ......... ,. ...... o,, .... °,,°,, .... ..,, ..... *,,,,**.,,,, °,,°,,,,,,,,,,°,,., .... **°, ...... ,,°°,***..°.,
2.2 Chemical Reactions..... .°.,,.,,.,. ..... ..,,°.,,,,,,°, ,,,,,, ,., ..... °.,,, .... ,,.. ........... ,, .... ,°,.,. .......... .. ....... 1.,° .....
2.3 Joint Preparation ......................................................................................................................
2.4 Qualitative Performance Rating ...................................................................................... : .......
3. FRICTION STIR WELDING OF A1 6092/17.5 SiCpFF-6 MMC'S .............................................
3. I Background ..............................................................................................................................
3.2 Experimental Procedures .........................................................................................................3.3 Results ....
.... °.**,,° .............. ,,,,., .... , ....................... .,.,.. .......... , .... , .... , .... . ...... ,, ................. , .... ** .... ,°
4. FSW OF FUNCTIONAL GRADIENT A1 MMC TO AI-Li 2195 .................................................
4. I Background ..............................................................................................................................
4.2 Experimental Procedures .........................................................................................................4.3 Results
...................... . .................... . ........ .....°............**°.....°..°*..... .... .°.......... .... . ..... ° ......... ....°....
5. TECHNOLOGY ASSESSMENT AND POTENTIAL APPLICATIONS .....................................
5.1 Performance Limitations of FSW ......................... °......°.....°......° ........ ... ....... ......................
5.2 Potential Applications for MMC Flanges ................................................................................
5.3 Other Potential Joining Techniques for MMC Flanges ...........................................................
6. CONCLUSIONS .................................... .................. . .............. .....o .......... . ......... .. .... . .... . .... . .... . ......
7. RECOMMENDATIONS......... . .......... . .... ..... ......... ***. ........... ... .... °.... ........... ...°.. ..... o ........ .....**.......
REFERENCES ....................................................................................................................................
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LIST OF FIGURES
o
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
Classification of selected joining methods for MMC's ....................................................
Schematic drawing of FSW process .................................................................................
FSW in action and the pin tool's geometric design ..........................................................
Comparison of hardness values for candidate coating materials ......................................
Cross-sectional view of an FSW joint for MMC's (x 10) ................................................
Change in SiC particle sizes and distribution at the HAZ's edge boundary .....................
Hardness measurement across the HAZ ...........................................................................
Development of FGM for MMC plates ............................................................................
FGM with 18.5-percent edge reinforcement welded to A1-Li 2195 .................................
Unsuccessful welding of 50-percent SiC MMC plate to A1-Li 2195 ...............................
MMC flanges reinforced with 50-percent SiC particulate for fuel line system ...............
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LIST OF TABLES
°
2.
3.
4.
5.
6.
Chemical compositions of 6092 AI alloy as the matrix material ..........................................
Typical properties of 6092 AI reinforced with 17.5-percent SiC particulate ........................
Empirical parameters developed for FSW of MMC's ..........................................................
MMC joint strength results using uncoated pin tool ............................................................
MMC joint strength results using B4C-coated pin tool ........................................................
FSW advantages and limitations for joining MMC's ...........................................................
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LIST OF ACRONYMS AND SYMBOLS
A!
A1-Li
A1203
AI4C 3
B4C
CIJ
FGM
FSW
HAZ
HRC
GMAW
GTAW
IFW
ipm
MMC
MSFC
NPA
RSP
SBIR
Si
SiC
TWI
UTS
WC
aluminum
aluminum-lithium
aluminum oxide
aluminum carbide
boron carbide
cast-insert joining
functional gradient material
fi-iction stir welding
heat-affected zone
hardness Rockwell "C" scale
gas metal arc welding
gas tungsten arc welding
inertia friction welding
inch per minute
metal matrix composite
Marshall Space Flight Center
nanophase aluminum
resistance spot welding
Small Business Innovative Research
silicon
silicon carbide
The Welding Institute
ultimate tensile strength
tungsten carbide
vi
TECHNICAL MEMORANDUM
FRICTION STIR WELDING FOR ALUMINUM METAL MATRIX COMPOSITES (MMC'S)
(MSFC Center Director's Discretionary Fund Final Report, Project No. 98-09)
1. INTRODUCTION
In order to fabricate certain structures from metal matrix composites (MMC's), effective joining
methods must be developed to join MMC's to the same or to different monolithic alloys. Since MMC's
utilize a variety of nonmetallic reinforcements such as silicon carbide (SIC), boron carbide (B4C),
aluminum oxide (AI203) ' graphite, etc., these nonmetallic reinforcements will naturally impose limita-tions for joining MMC's using conventional methods for monolithic metals.
This report describes an investigation into the use of the friction stir welding (FSW) process for
joining a variety of AI MMC's reinforced with discontinuous SiC particulate and functionally gradient
material (FGM). FSW is a fairly new solid state welding process for joining metals by plasticizing andconsolidating materials around the bond line using thermal energy produced from localized friction
forces. The process does not require the need for gas shielding or filler metal. The FSW process consists
of a special rotating pin tool that is positioned to slowly plunge into the MMC surface at the bond line.
As the tool rotates and moves forward along the bond line, the material is heated up and forced to flow
around the rotating tips, forming a solid state joint. FSW has the potential for producing sound welds
with MMC's because the processing temperature occurs well below the melting point of the metal,
thereby reducing the reinforcement-to-matrix solidification defects and undesirable chemical reactions.
Preliminary results show that FSW is feasible to weld A1 MMC's to MMC's or to aluminum-
lithium (AI-Li) 2195 if the SiC reinforcement is <25 percent by volume. Tensile strength, hardness, and
microstructure of these welds were characterized in both the as-welded and post heat treatment condi-
tions. However, a softening in the heat-affected zone (HAZ) was observed and is known to be one of the
major limiting factors for joint strength. The pin tool's material is made from a low-cost steel tool H-13
material, and the wear was excessive such that the pin tool length had to be manually adjusted for every
5 ft of weldment. Initially, B4C coating was developed for pin tools, but it did not show significant
improvement in wear resistance. Basically, FSW is applicable mainly for butt joining of flat plates.
Therefore, FSW of cylindrical articles such as a flange to a duct, with practical diameters ranging from
2-5 in., must be fully demonstrated and compared with other proven MMC joining techniques.
2. POTENTIAL ISSUES IN JOINING MMC'S
2.1 Solidification Effects
In general, MMC's utilize a variety of nonmetallic reinforcements with a typical volume fraction
ranging from 5 to 60 percent. For this reason, there are several potential joining issues that are peculiar
to MMC's such as the solidification effects. Since most nonmetallic reinforcements have different
densities from the metal matrix, this can lead to pronounced particle segregation effects when the matrix
is in the molten state. Below a certain critical solidification temperature, reinforcements can be pushed
ahead of the solidification front, resulting in nonuniformity of the reinforcement in the weld region.
Under the molten state, the composite rnetal weld pool generally has a higher viscosity and does not
flow as well as the unreinforced metal matrix. High viscosity can often lead to a lower heat transfer by
convection mechanism in the weld pool, which can affect the resulting microstructures and the stress
distributions in the MMC's. Solidification effects are difficult to control and commonly encountered in
most fusion welding techniques. Solidification problems may result in dissolution of the reinforcements
and nonuniform packing density due to the migration of the reinforcement into the weld regions. Most
conventional fusion welding techniques such as arc welding, electron-beam welding, and laser-beam
welding can fundamentally be considered as miniature castings with different boundary conditions and
complex solidification effects.
2.2 Chemical Reactions
In the past, there were some fusion welding techniques that have been used with moderate
success on some types of particulate reinforced MMC's. However, the major difficulty with fusion
welding for MMC's is that prolonged contact between a molten-metal matrix and particulate reinforce-
ments can lead to undesirable chemical reactions. For instance, liquid phase AI will react with SiC
reinforcement to precipitate the aluminum carbide (A14C3) and increase the silicon (Si) content upon
cooling down the molten metal matrix. Similarly, carbon or graphite will react with A1 or certain types of
metal matrices at high processing temperatures to form detrimental phases. In the presence of moisture,
metal carbides can decompose with the release of hydrocarbon gases and increase the joint susceptibility
to corrosion cracking and joint strength degradation. Consequently, the chemical compatibility of the
metal to reinforcement for a specific joining method is material and process specific. Most fusion pro-
cesses are high thermal energy processes that are not easily applied to MMC's. For example, experimen-
tal data suggested that the laser energy is preferentially absorbed by most nonmetallic reinforcements in
the very narrow weld regions of high heat flux. Therefore, fusion welds must be automated with high
welding speed and temperature control in order to reduced undesirable chemical reaction.
2.3 Joint Preparation
Because of their nonmetallic reinforcements, MMC's tend to have low ductility; high surface-
wear resistance; and high brittleness to machine, cut, or drill using standard steel cutting tools and saw
blades.Most MMC's with highreinforcementvolumerangingfrom 40 to 60percentwill behavemorelike ceramicthanmonolithic metalsandcanbecomedifficult to cutor machine.In preparationfor anMMC joint prior to welding,thecuttinganddrilling parameterssuchasspeedandforcemustbecare-fully controlledin orderto avoidcompositepaneltearoutor crack.To avoidexcessivetool wear,it is acommonpracticefor diamond-or diamond-like-coatedsteeltoolsto beemployedfor MMC's.
2.4 Qualitative Performance Rating
Figure 1 shows that the major joining methods for MMC's can be classified into three main
groups: (1) Solid state, (2) fusion, and (3) other processes. Presently, it is important to realize that the
joining technology is not mature for MMC's, and many important joining technical details are still
lacking. I Consequently, the precise knowledge of the adaptability of a specific joining method, including
FSW in this study, is a specific material and process-dependent factor which must be determined experi-
mentally. As a general rule, the adaptability of any joining techniques for MMC's will depend on the
combination of the following factors: (I) The volume percent amount and types of reinforcements,
(2) the metal matrix meIting point, and (3) the thermal energy management fi'om the selected joiningprocess. A brief summary of these three factors is given as follow:
Since MMC's utilize a variety of nonmetallic reinforcements, the higher the reinforcement volume
fraction, the less likely for standard metal joining techniques to adapt. Discontinuously reinforced
MMC's are easier to join than continuously reinforced MMC's using fibers which are prone to
matrix fiber debonding, delamination, nonuniform fiber packing density, and migration of fibersbundled into the weld regions.
The prolonged contact time between a molten-metal matrix and a reinforcement can lead to undesir-
able chemical reactions that are accelerated as the molten-metal temperature increases. Therefore,
the metal matrix reinforcement chemical compatibility is a material- and temperature-dependent
factor. For this reason, the higher the metal matrix melting temperature, the less likely most of thefusion techniques are to adapt.
Although high thermal energy is required for most conventional joining processes, excessive thermal
energy input is undesirable. Therefore, the use of an automated joining process or a special joining
method that can offer a well-controlled, thermal-energy input in a minimum process time will likelyimprove the joining adaptability for MMC's.
3
I
[Inertia Friction WeldingFrictioin Stir WeldingUltrasonic WeldingDiffusion Bonding
MMC JoiningMethods
Laser BeamWeldingElectron BeamWeldingGas Metal Arc Welding
GasTungsten Arc WeldingResistanceSpot WeldingCapacitorDischarge Welding
IIO*_er_oce_e_l
BrazingSolderingAdhesive BondingMechanical FasteningCast-Insert JoiningTransient Liquid Phase
Rapid Infrared Joining
Figure 1. Classification of selected joining methods for MMC's.
4
3. FRICTION STIR WELDING OF Ai 6092/17.5 SiCp/T-6 MMC's
3.1 Background
FSW is a relatively new joining process that was originally developed and patented by The
Welding Institute (TWI) of Cambridge, England." Since 1993, FSW has been studied and demonstrated
by many researchers.3-5 However, FSW can best be described in conventional terms as a combination of
extrusion and forging of metals at elevated temperatures. The process is considered as a solid stateprocess, and it does not require the need for gas shielding or filler metals.
Figure 2 is a schematic describing the FSW process. FSW consists of a rotating and nonconsum-
able pin tool that is slowly plunged into the bond line until the pin tool's shoulder is in intimate contact
with the workpiece. As the tool rotates and moves forward along the bond line, the material at the bond
line begins to heat up, forcing it to flow around the rotating tip to consolidate on the pin tool's backside.
This heat source is developed mainly due to the local friction and plastic deformation while keeping the
pin tool's shoulder in intimate contact at all times with the workpiece. The workpieces must be securely
clamped to a backing anvil in a manner that prevents them from moving and being forced apart at the
abutting joint faces. Interestingly, FSW has the potential for welding MMC's because the processing
temperature occurs well below the metal's melting point, thereby eliminating the solidification defects
and undesirable chemical reactions. However, as with all welding processes, FSW has its advantages anddisadvantages which will be briefly reviewed in this study.
Rotationof Tool Friction Stir Weldingand VerticalForce Pinand ShoulderTool
FrictionHeated WorkpieceMetalBy PinTool Workpiece
SideView
PlasticizedMetalLayerBeneathShoulderandAroundPinTool
Regionof WeldedMetalSeam
+ Directionof Travel
FrontView
FrictionStir WeldingCharacteristics
Rotatingsteel pinandshouldertool frictionheatsthe abuttingfaces.As the tool movesalongtheseamline, plasticizedmetal is mechanicallystirred andweldedtogetherby forging.
Processingtemperatureoccurs well below metalmeltingpoint.
No toxic fumes,heat,andarc flashes.
Figure 2. Schematic drawing of FSW process.
5
3.2 Experimental Procedures
The pin tools used were specifically designed for this study to accommodate the 0.125-in.-thick
plates, and the tool length can be manually adjusted for variation in plate thicknesses prior to welding.
As shown in figure 3, the tools had a 0.475-in.-diameter shoulder and 10-24 unified coarse left-handed
threads on the pin. A computer simulation was used to determine the optimum pin tool length of
0.120 in. for making an optimum full-penetration weld. This pin tool was independently designed by
Robert Carter, the Co-Principal Investigator, and does not contain proprietary design information.
Figure 3. FSW in action and the pin tool's geometric design.
Due to the highly abrasive nature of this particular MMC, excessive pin tool wear was expected.
For this reason, two sets of pin tools having identical geometry but different wear-resistant coating were
applied. Both sets were fabricated from H-13 tool steel that was heat treated to 53-55 HardnessRockwell "C" (HRC) scale. One set was then coated with B4C to achieve a surface hardness value of
93-95 HRC. The other tool set was left uncoated. The B4 C was chosen as a coating due to its potential
for outstanding wear resistance, superior lubricity, good corrosion, and chemical resistance. The coating
was applied using a low-temperature, low-cost process. Figure 4 shows a hardness comparison of several
coating materials that were considered for this study. Furthermore, B4C coating was chosen for the
initial trials due to its low cost factor.
As shown in figure 3, FSW was performed using the Kearney & Trecker five-axis horizontal
computer numerical control milling machine that was modified for FSW. After welding, the panels were
x-rayed, and root side die-penetrated tests were performed. The welded panels were then cut and
machined into tensile specimen coupons and microstructure analysis specimens. The specimens were
tensile tested in as-welded conditions and in post heat-treated T6 conditions. The T6 condition specifica-
tions were recommended by the manufacturer and consisted of solution heat treating at 1,030 °F for 3 hr,
then water quenching. It was followed by age hardening at 325 °F for 8 hr and then air cooled.
Coating Materials HardnessValues in Rockwell "C" Scale
Diamond
Boron Carbide
Titanium Carbide
Silicon Nitride
Chromium
High-Speed Steel
100
95
9o
9o
7o
6o
Figure 4. Comparison of hardness values for candidate coating materials.
The MMC material used in this study was a 6092 A1 alloy reinforced with 17.5-percent SiC
particulate which is homogeneously distributed throughout the matrix. The material was supplied by
DWA Aluminum Composites, Inc., Chatsworth, CA, in the form of 6x12x0.125-in. plates with T6 heat
treatment condition prior to welding. Table I shows the chemical compositions of 6092 Ai alloy, and
table 2 shows some of the physical and mechanical properties which were provided by the material
supplier,6 DWA Aluminum Composites, Inc.
Table 1. Chemical compositions of 6092 Al alloy as the matrix material.
CompositionsElement (wt. %)
Silicon
MagnesiumCopperManganeseChromiumZincTitaniumIron
OxygenAluminum
0.4-0.80.8-1.20.7-1.0
0.15 (max.)0.I5 (max.)0.25 (max.)0.I5 (max.)0.3 (max.)0.05-0.5Balance
Table 2. Typical properties of 6092 A1 reinforced with 17.5-percent SiC particulate.
Property Value/Description
Material Descriptor 6092/SiC/17.5p-T6Reinforcement Type 17.5% SiCParticulates
Density (Ib/in3)Ultimate tensile strength (ksi)Yield strength (ksi)Elongation (percent)CTE(ppm/F)Hardness (Rockwell "B")Temper
0.101675789.382T-6
Table 3 lists the FSW parameters and their description that were experimentally developed for
this study to yield sound welds. These parameters were used as guidelines for FSW of MMC's. It should
be noted that these parameters were chosen for a feasibility study and have not been fully optimized.
Tool wear was monitored by measuring pin tool dimensions before and after each weld. The uncoated
tools were used in the beginning of the study to develop acceptable welding parameters and to generate
data using the chosen set of parameters. The B4C-coated tools were used in the latter part of this study to
generate data using the chosen parameters.
Table 3. Empirical parameters developed for FSW of MMC's.
FSWParameters Value Description
TravelspeedRotatingspeedLeadanglePlungedepthPenetrationligament
4 ipm1,350rpm2.5 deg0.010in.0.005in,
Inch-per-minutehorizontalspeedRotatingspeedof pin toolPintool's tiltinganglefromverticalplaneShoulderlengthplungesbelowcrownsideDistancebetweentip of pinandbackinganvil
3.3 Results
3.3.1 Microstructure Analysis
No evidence of cracking was found within the cross-sectional view of the welds as observed by
optical microscopy at x 400. However, visual inspection easily revealed that the crown side (top side) of
the welds was quite coarse. In comparison with monolithic alloys, the crown side of a typical FSW in an
AI alloy has a highly polished, machined appearance. The welds performed with MMC material consis-
tently gave the crown side a unique appearance_that is rernin]sc-ent 0_ what one would expect to see for a
typical surface of concrete. This coarse appearanc e was caused.=.=.==bY-_the fact that the SiC particles did notadhere well with the AI at the surface of the weld adjacent to thg tool shoulder. It was noticed that the
anomaly was partially overcome with the use of B4C-coated tOOlS which had a higher hardness and a
lower lubricity, allowing the material to coaiesee much better. However, after only a few inches of
welding, the SiC particles were already beginning to wear the B4C off the outer edge of the tool shoul-
der. Once the coating was worn off, the coarseness reappeared. This coarseness appeared to be only a
surface anomaly and did not seem to have any significant influence on the tensile properties. Figure 5
shows the cross-sectional view of an FSWjoint using an uncoated pin tool.
Figure 5. Cross-sectional view of an FSWjoint for MMC's (x 10).
It was noticed that on the root side of some MMC welds, occasionally some panels were actually
"stuck" to the backing anvil after being welded. This phenomenon occurred when the material directly
beneath the pin and adjacent to the backing anvil became welded to the anvil due to the heat and extreme
pressure created by the welding process in this zone. Observations of intermittent "craters" on the root
side indicated places where material "stuck" to the backing anvil when the workpiece was removed.
Such small craters were identified using a conventional die-penetrated technique, and these defects
appeared to be very shallow surface defects which may not significantly influence the mechanical
properties of the welds. Figure 6 shows an interesting microstructure at the edge of the HAZ at x 400.
Evidently, the SiC particles were broken up by the pin tool and became smaller as they traveled toward
the center of the HAZ. Also, there was a lack of high-volume particle concentration at the edge of theHAZ.
(a)Cross-sectionalviewof FSWjoint (Magnification:x 4). (b) Microstructureof FSWjoint (Magnification:x 400).
Figure 6. Change in SiC particle sizes and distribution at the HAZ's edge boundary.
3.3.2 Tensile Strength Measurements
In order to access the joint efficiency of these MMC welds, tensile strength was measured and
the joint efficiency was calculated as follows. Using the uncoated tool, the average ultimate tensile
strength (UTS), measured at room temperature, was 41.4 ksi when tested in the as-welded condition.
Tensile strength of 54.7 ksi was obtained when tested after heat treatment and age hardening back to the
original T6 condition. The average UTS of welds performed with B4C coated tools was 43.3 ksi when
tested in the as-welded condition and 61.9 ksi when tested in the postheat-treated T6 condition. Tables 4
and 5 show the tensile data for FSW of MMC panels using an uncoated and coated pin tool, respectively.
To evaluate the joint efficiency, the parent material's UTS was experimentally determined to be =60 ksi.
It was noted that this value is = 10 percent less than the UTS value reported in the literature. From the
experimental value of 60 ksi, the joint efficiency of 61-72 percent was achieved in the as-welded condi-
tion and 92-100 percent after heat treatment. In general, coating the pin tool does not seem to alter the
joint efficiency in comparison with an uncoated pin tool.
Table 4. MMC joint strength results using uncoated pin tool.
JointProperty As-Welded HeatTreated
Modulus(Msi) 11.13Yieldstrength(ksi) 27.7Tensilestrength(ksi) 41.42-in. elongation(%) 2.49
12,2849.157.72.07
Table 5. MMC joint strength results using B4C-coated pin tool.
JoinlProperty As-Welded
Modulus(Msi) 10.44Yieldstrength(ksi) 27.4Tensilestrength(ksi) 43.52-in. elongation(%) 2.72
HealTreated
12.8355.161.92.00
3.3.3 Hardness Measurements
Hardness measurement was taken across the crown side of the weld zone as shown in figure 7.
These welds were performed with B4C-coated pin tools. From the hardness measurement, it was con-
cluded that the yield and tensile strengths were also reduced greatly in the HAZ by overheating due to
the FSW process. In general, coating of the pin tool does not seem to alter the HAZ hardness measure-
ment profile in comparison with an uncoated pin tool. Although thermal energy is required for most
joining processes, it becomes obvious that any excessive thermal energy input is undesirable, including
FSW in this study.
3.3.4 Pin Tool Wear
The pin tool's wear was found to be most significant on the outer edge of the tool shoulder and
on the major diameter of the pin's thread form. On the average, =0.0005 in. of material was removed
from the tool shoulder per linear foot of weldment, and the pin diameter was reduced by 0.010 in./ft of
weld. This wear was manageable without manual pin tool length adjustment for weldment of =5 ft or
less. In other words, for every 5 ft of welds, the pin tool's length must be removed from the welding
head and manually adjusted for the next weld session.
10
FSW Pin To_
I PlateA
90
"" 80'
70-
60-
50-
4O
3O0
Weld Centerline
HeatAffected Zone
Postheat
Treatment
• //
"*_ . As-Welded " "" i,#'/_"
o.2 '0.4 016 0.8 1 112gislance (in.)
Figure 7. Hardness measurement across the HAZ.
!1
4. FSW OF FUNCTIONAL GRADIENT AI MMC TO AI-Li 2195
4.1 Background
Previous studies of several methods of joining MMC's have shown that the higher the reinforce-
ment volume fraction the less likely for standard metal joining techniques to adapt. 7 Therefore, in order
to increase the joining adaptability by decreasing the reinforcement at the bond line, a unique joining
method was developed which was somewhat similar to the cast-insert joining (CIJ) technique as listed
in figure 1. The CIJ is a method of near net- shape casting of MMC components with built-in metallic
inserts or metallic-like materials to provide a site joining with another metal or MMC using any
conventional joining technique.8
Using the CIJ concept, several MMC plates were produced through the near net-shape pressure
infiltration process, with low reinforcement volume fraction using thin strips of "insert" material along
the welding edges of the plate as shown in figure 8. These FGM MMC plates contain up to =50-percent
SiC particulate reinforcement by volume which is uniformly distributed everywhere except near the
edges of the plate. Along these edges, the reinforcement concentration level can be made to drop to 5,
18.5, and 27 percent by using a special ceramic preform material called Saffil paper with a typical
thickness of 0.25 in. One of the objectives of this project was to investigate the feasibility of FSW these
FGM plates to A1-Li 2195.
T4 in.
.°.0.0e.th.ssI IF-..e-,h5°.erce.IReinforcement Material SiC Reinforcement
T0.25 in.
:.:!.i !;ili;ili!ii!iiiiiiii i!iii ;! {; i;i;i}};.}}.iiiiii il;;i;ii!iiii i : :i:ii
12in.
Figure 8. Development of FGM for MMC plates.
12
4.2 Experimental Procedures
4.2.1 Pin Tool Geometry
From the previous study of FSW of 0.125-in.-thick MMC plates reinforced with 17.5 percent SiC
particulate, a slight modification for the pin tool geometry was performed. All pin tools were threaded
with a unified fine 20-pitch, left-handed thread with a nominal length of 0.230 in. The pin tool'sshoulder diameter was 0.738 in.
4.2.2 Welding Parameters
The nominal material thickness for all welds made was 0.250 in. The initial welding parameters
were developed based on FSW of AI-Li 2195 to AI-Li 2195 plates with identical thicknesses of 0.250 in.
By trial and error, a set of welding parameters developed for welding 2195 to 2195 were given as fol-
lows: Spindle speed--700 rpm, travel speed-_ ipm, and shoulder plunge depth--0.010 in.
4.3 Results
4.3.1 Welding Trial No. 1 (2195 to 50-Percent SiC FGM With 5-Percent Saffil Edge)
This weld was initiated using the parameters developed for welding 2195 to 2195. It was
observed that the weld was not "hot" enough, and the transverse travel speed was reduced from 4 to
3.4 ipm at ---3.5 in. into the weld in order to increase heat input and promote weld quality. Visual inspec-
tion of this weld from the crown side (.top side) appeared to be of good quality. However, the pin tool
shoulder did not plunge far enough into the material, because of the unexpected high wear-resistant
property and stiffness values from the MMC plate. It is expected that a slight adjustment of the pin tool
length and plunge depth would overcome this typical problem.
4.3.2 Welding Trial No. 2 (2195 to 50-Percent SiC FGM With 18.5-Percent Saffil Edge)
Based on the results of welding trial No. 1, new parameters were adjusted and given as follows:
Spindle speed--700 rpm, travel speed--3.5 ipm, and shoulder plunge depth--0.015 in. Visual inspection
of this weld from the crown side appeared to be of very good quality. Figure 9 is a photograph showing
the result of this welding trial.
Figure 9.
3cYJ),--"
FGM with 18.5-percent edge reinforcement welded to A1-Li 2195.
13
4.3.3 Welding Trial No. 3 (2195 to 50-Percent SiC FGM With 27-Percent Saffil Edge)
This weld was performed based on the same parameters used in weld No. 2. The beginning of the
weld had an excessive material loss due to "flash." This was caused by excessive heat input to the 2195
side of the weld and resulted in a lack of material consolidation. The speed was increased from 3.5 to
4 ipm at 1.5 in. into the weld in order to reduce the heat input to the 2195 side. At 6 in. into the weld the
pin tool broke off due to excessive loading force. It was speculated that this situation was caused by a
mismatch in the ductility or plastic zone side due to the difference in forging temperature and thermal
conductivity between the MMC and the 2195 material. Indeed, previous experiments performed at
Marshall Space Flight Center (MSFC) for FSW of A! to copper (Cu) were not successful. Therefore, as
dissimilar material properties become more diverse, it will become very difficult to perform a sound
FSW.
4.3.4 Welding Trial No. 4 (2195 to 50-Percent SiC With No FGM)
This weld was performed using the same parameters as weld No. 2. The weld was unsuccessful
due to very high reinforcement volume at the welding edge of the plate. In this weld the pin broke off
after only 1.5 in. of weld. Another trial was performed with a similar result: the pin tool broke off again
after <1 in. of weld. It is speculated that with the 50-percent SiC reinforcement, there is a large mis-
match in the plastic zone size between the MMC and 2195 material, thus making this weld nearly
impossible. Similarly, a previous experiment performed at MSFC for FSW of A1 to Cu was not success-
ful due to the same reasons. Therefore, as stated in the paragraph above, as dissimilar material properties
become more diverse, it will become very difficult to perform a sound FSW. Figure 10 is a photograph
showing the result of this unsuccessful welding trial without FGM.
Figure 10. Unsuccessful welding of 50-percent SiC MMC plate to A1-Li 2195.
14
5. TECHNOLOGY ASSESSMENT AND POTENTIAL APPLICATIONS
5.1 Performance Limitations of FSW
As with all welding processes, FSW has specific advantages and limitations for MMC's, as listed
in table 6. The FSW process may be considered as a joining method that utilizes a combination of
extrusion or forging of metals at elevated temperatures. Therefore, as dissimilar material propertiesbecome even more diverse, it will become more difficult to perform a sound FSW.
Table 6. FSW advantages and limitations for joining MMC's.
Advantages
Operatebelow melting point to prevent undesirablechemical reactionsNo solidification defects between reinforcement and metalPerform at ambient conditions with no toxic fumesMinimum shrinkage, distortion, and residual stress
Simple control processwithout gas shielding or filler material
PerformanceLimitations
Processportability is limited by the need for heavy and large backing anvilPin-tool wear may besevere for MMC with reinforcement of >20 percentSound weld for AI MMCto 2195 AI alloy limited to reinforcment of <25 percentLimiting joint strength to <65 percent due to high processing temperatureWelding MMC flat plate or large curvature surface only
The adaptability of FSW or any of the solid state joining techniques for MMC's will depend on
the volume percent amount, the types of reinforcements, and the thermal energy input from the joining
process. In this study, it was found that the FSW process for MMC's was limited to =25-percent SiC by
volume fraction. Above this value, pin tool wear resistance may become too severe. Most importantly, it
was found that a higher material properties mismatch between the MMC and the monolithic alloy to be
welded would make FSW very difficult to apply. The thermal energy created by the FSW process was
also high enough that the yield and tensile strengths were also reduced greatly in the HAZ. Historically,
FSW is applicable mainly for butt joining of flat plates. Therefore, FSW of cylindrical articles (e.g., a
flange to a duct) with diameters ranging from 2-5 in. must be fully demonstrated and compared withother conventional joining techniques as described in figure i.
5.2 Potential Applications for MMC Flanges
5.2.1 Potential Applications
There are several MSFC ongoing activities in the development of MMC's for advanced liquid
rocket engines such as the X-33 vehicle's Aerospike and X-34's Fastrac engine.9 In most of these MMC
15
applications, it was found that FSW either cannot be applied efficiently or will not be required, with the
exception of the potential application of joining an MMC flange to an A1 duct. Figure 11 shows thestate-of-the-art fuel line flanges which are made with AI MMC's reinforced with 50-percent SiC or B4C
particulate. For reference, these typical flanges are 1.90 _n. high and have a 6.5-in. outside diameter with
a 4-in.-diameter port hole. Each of these MMC flanges would weigh =913 g. The future fuel line duct is
proposed to be either A1-Li 2195 alloy or the nanophase A1 (NPA) alloy. For this reason, the feasibility
of FSW of MMC plates to A1 2195 plates was investigated in this study as a preliminary assessment of
FSW of MMC flanges to A1 ducts. It was found that FSW was fairly good when the MMC contained
<25-percent reinforcement and it was nearly impossible to weld when the reinforcement value reached
50-percent volume fraction.
Figure 11. MMC flanges reinforced with 50-percent SiC particulate for fuel line system.
5.2.2 Functional Gradient Material
One innovative method to improve the joining process for the MMC flanges is to develop them
with FGM features in order to reduce the volume fraction at the bond line. These FGM flanges as well as
the FGM flat plates are currently being made under a Small Business Innovative Research (SB1R) phase
2 contract for MSFC with Metal Matrix Cast Composites, Inc., Waltham, MA. These FGM articles are
produced through a net-shape, pressure-infiltration process with low reinforcement volume using thin
strips of "insert" material along the welding edges. Along the bond lines, the reinforcement volume level
can be made to drop from 50 percent to 27, 18.5, and 5 percent by using a special ceramic preform
material layer called Saffil. Most importantly, FGM technology may allow other joining methods to be
used more effectively than FSW for joining of MMC flanges.
5.3 Other Potential Joining Techniques for MMC Flanges
It is speculated that if FGM is applied for the development of MMC's, it may allow other joining
methods to be used in addition to FSW for MMC flanges. Historically, FSW is applicable mainly for
butt joining of flat plates. However, cylindrical articles having small diameters of <2-5 in. have not been
fully demonstrated. There are several solid state and fusion welding techniques that may be applied for
FGM of MMC flanges, depending on the duct's material and performance requirements. If the ducts are
16
madefrom NPA,thenonly solidstateweldingtechniquescanbeappliedto maintaina low processingtemperaturefor NPA.If theductsaremadefrom anAI-Li alloy suchas2195,thenfusionweldingprocessesmaybeused,dependingon theflangedesignandrequirements.Suggestionsfor solidstateweldingtechniqueswhich maybeapplicablefor MMC flangesareinertia friction welding(IFW) anddiffusion bonding.Suggestionsfor fusionprocessesarelistedasgasmetalarcwelding(GMAW), gastungstenarcwelding(GTAW),andresistancespotwelding(RSP).Theseweldingtechniquesarecapablefor weldingeitherflat platesor cylindricalarticlesthathavea smallradiusof curvature.In thisstudy,aliteraturesurveyfor weldingMMC cylindricalarticlesrevealedthat IFW andGMAW wereusedsuc-cessfullyin thepastfor weldingof cylindricalMMC componentsto monolithicalloys.Therefore,asummaryof thepotentialweldingtechniquesthatmaybeapplicablefor NASA'sapplicationsareshownbelow.
5.3.1 Inertia Friction Welding
Interestingly, IFW has proven very successful in the past for making sound MMC joints for
cylindrical objects that have a small radius.J0-1;' It was noted that some of the welds between MMC and
monolithic AI could exhibit an excellent room-temperature joint strength of 83 percent of the value of
the composite base material. Yield strength values in cross-weld tensile of up to 90 percent of parent
material value have been obtained by IFW. In fact, the cylindrical geometry of the duct and flange to be
mated would directly allow the use of this technique with potentially very little preparation and no
speciaI tooling. Basically, the method is simply described as making one workpiece to be rotated and
keeping the other stationary. Then, the two workpieces are brought together under a compressive con-
tacting force to form a solid state weld. IFW has been widely used for joining dissimilar materials and
exhibits several important characteristics that make it a viable candidate for welding MMC flanges andducts.
5.3.2 Gas Metal Arc Welding
This fusion welding process can be used for low volume reinforcement of MMC. Experimental
results fi'om A/can International have shown that it was possible to weld 4-in.-diameter (10-cm) MMC
driveshafts to monolithic A] yokes for automotive applications. 13-15 It was noticed that the MMC mate-
rial at 20-percent A1203 reinforcement was much easier to weld than the um'einforced AI, because this
type of reinforcement made the weld pool more viscous. Furthermore, demonstration of several seamless
tubes with wall thicknesses of 2 mm (0.08 in.) were successfully welded to foxed 6061 AI yokes. The
GMAW process with 5356 AI filler wire was used in the standard driveshaft MMC assembly fixtures forfull-scale component demonstration.
17
6. CONCLUSIONS
FSW can be applied for discontinuously reinforced MMC"s when the reinforcement is <25 per-
cent by volume. Above this level, FSW is difficult to apply due to the material's high brittleness, high
wear resistance, high stiffness, low ductility, high forging temperature, and low thermal conductivity. For
similar reasons, previous FSW experiments performed at MSFC for A1 to Cu were not successful.
The pin tool's wear was found to be excessive, even when reinforcement was limited to 17.5 per-
cent SiC by volume, such that the pin tool's length had to be manually adjusted for every 5 ft of weld.
However, higher tool wear resistance for future materials such as tungsten-carbide, etc., must be able to
be machined and may require high fracture toughness to prevent the pin tool from breaking off due to
excessive welding force.
In this study, cost-effective B4 C coating did not work for the H-13 steel tool to prevent pin tool
wear against MMC's. High processing cost but potentially better wear-resistance coating materials such
as diamond and diamond like materials may need further investigation for FSW.
FSW has shown to release an excessive amount of thermal energy for welding MMC. Evidently,
a softening in the HAZ was observed for all of the welds in this study, which is one of the major limiting
factors for joint strength. The joint efficiency of 65 percent was achieved in the as-welded condition for
6092/SiC/20p-T6.
Historically, FSW is applicable mainly for butt joining of flat plates and of curved plates that
have a large radius of curvatures. It is speculated that below certain small values for radius of curvature
FSW may become very difficult to apply, in particular for small circular MMC flanges to cylindrical
metal ducts.
If FGM is utilized for the development of MMC's, it may allow other joining methods to be used
in addition to FSW for MMC flanges. A literature survey suggested that there are other potential welding
techniques for MMC flanges such as the 1FW and GMAW. In particular, IFW has been used successfully
for welding small cylindrical MMC components such as tubes and driveshafts for automotive
applications.
18
7. RECOMMENDATIONS
It is recommended that FGM be developed as a method to reduce the reinforcement volume at
the bond line in order to improve the joining processes for MMC flanges. FGM is an innovative material
approach that could allow other potential MMC joining methods to be used more effectively than FSW,
particularly for joining small cylindrical objects such as MMC flanges, ducts, and tubes with practicaldiameters ranging from 2 to 5 in.
It is recommended that IFW, GMAW, GTAW, and RSP be developed for joining of MMC
flanges and ducts. These welding techniques are capable of welding cylindrical articles with a small
radius of curvature. A literature survey for welding MMC cylindrical articles revealed that IFW and
GMAW were used successfully and extensively in the past for welding cylindrical MMC componentssuch as driveshafts and thin-walled tubes to monolithic alloys.
It is recommended that higher pin tool wear-resistant materials or coatings be developed for
MMC's with >25-percent reinforcement. However, high wear-resistant pin tool materials must also
exhibit the ability to machine well and have good fracture toughness to prevent breaking off under highFSW welding force.
It is recommended that FSW of cylindrical articles such as MMC flanges to A1 ducts, with
realistic NASA propulsion hardware applications for practical diameters ranging from 2-5 in., be fully
demonstrated and compared with other proven MMC joining techniques for cylindrical articles.
I9
REFERENCES
. Lee, J.A.: "Section: 1.2.8.4 Joining Methods for MMC," In: Metal Matrix Composite Handbook, to
be published by the Department of Defense.
2. Thomas, W.M.; et al." "Friction Stir Welding," U.S. Patent 5,460,317.
3. Dawes, C.J.; and Thomas, W.M.: "Friction Stir Process Welds Aluminum Alloys," Welding Journal,
pp. 41-45, March 1996.
4. Midling, O.T.; "Material Flow Behavior & Microstructural Integrity of Friction Stir Butt
Weldments," Fourth Inter. Conf. Aluminum Alloys, pp. 451-458, September 1994.
5. Rhodes, C.G.; Mahoney, M.W.; et al.: " Effects of Friction Stir Welding on Microstructure of
7075 Al," Script. Metall., Voi. 36, pp. 69-75, 1997.
6. Database provided by Mark van den Bergh from DWA Aluminum Composites, Inc.
,
.
Lee, J.A.: "Technology Assessment of Commercial Joining Techniques for MMC, " 21st Conf. on
Composites, Materials and Structures, Cocoa Beach, FL, January 27-31, 1997.
Lee, J.A.; and Kashalika, U.: "Casting of Weldable Gr/Mg MMC with Built-in Metallic Inserts,"
NASA Conf. 3249, Voll 1, p. 371, Anaheim, December 7-9, 1993.
9. Lee, J.A." "Potential Applications of Al MMC for NASNs Advanced Propulsion Systems,"
23rd Conf. on Composites, Materials and Structures, Cocoa Beach, FL, January 25, 1998.
10. Gittos, M.; and Threadgill, P.: "Joining Aluminum Alloy MMC," Bulletin 5, TWI J., pp. 104-105,
September/October 1992.
11. Abeam, J.S.; and Cooke, D.C.: "Joining Discontinuous SiC Reinforced A1 Composites," Martin
Marietta Co., Report: NSWC-TR-86-36, September 1, 1985.
12. Cola, M.J.; et al.: "Inertia Friction Welding of Aluminum 6061-T6/A1203 MMC," Research Report
MR9108, Edison Welding Institute, June 1991.
13. Altshuiler, B.; Christy, W.; and Wiskel, B.: "GMA Welding of Al-Alumina MMC,'" Weldability of
Materials, ASM International, pp. 305-309, Materials Park, OH, 1990.
2O
14. Lienert,T.; Lane,C.; andGould, J.: "SelectionandWeldabilityof A1 MMC," ASM Handbook,
Vol. 6, pp. 555-559, Materials Park, OH, 1995.
15. Schwartz, M.M.: "Joining of Composite Matrix Materials," ASM hlternational, pp. 98-100,
Materials Park, OH, 1995.
21
Form ApprovedREPORT DOCUMENTATION PAGE OMBNo.0704-0188
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1. AGENCY USE ONLY (Leave Blank) 2. REPORT DATE 3. REPORT TYPE AND DATES COVERED
December 1999 Technical Memorandum
4. TITLE AND SUBTITLE 5. FUNDING NUMBERS
Friction Stir Welding for Aluminum Metal Matrix Composites
(MMC's)(MSFC Center Director's Discreli0nar_' Ft, nd Final Report, Pro iect No. 98-09)6. AUTHORS
J.A. Lee, R.W. Carter, and J. Ding
7. PERFORMING ORGANIZATION NAMES(S) AND ADDRESS(ES)
George C. Marshall Space Flight CenterMarshall Space Flight Center, Alabama 35812
9. SPONSORING/MONITORING AGENCY NAME(S) AND ADDRESS(ES)
National Aeronautics and Space Administration
Washington, DC 20546-0001
8. PERFORMING ORGANIZATION
REPORT NUMBER
M-953
10. SPONSORING/MONITORING
AGENCY REPORT NUMBER
NASA/TM--1999-209876
11. SUPPLEMENTARY NOTES
Prepared for Materials Processes and Manufacturing Department, Engineering Directorate
12a. DISTRIBUTION/AVAILABILITY STATEMENT
Unclassified-Unlimited
Subject Category 29Nonstandard Distribution
12b. DISTRIBUTION CODE
13, ABSTRACT (Maximum 200 words)
This technical memorandum describes an investigation of using fi'iction stir welding (FSW) process for
joining a variety of aluminunl metal matrix composites (MMC's) reinforced with discontinuous silicon-carbide (.SIC) particulate and functional gradient materials. Preliminary results show that FSW is feasible [oweld aluminum MMC to MMC or to aluminum-lithium 2195 if the SiC reinforcement is <25 percent by
volume fraction. However, a softening in the heat-affected zone was observed and is known to be one of the
major limiting factors for joint strength. The pin tool's material is made fi'om a low-cost steel tool H-13material, and the pin tool's wear was excessive such that the pin tool length has to be manually adjusted for
every 5 ft of weldment. Initially, boron-carbide coating was developed for pin tools, but it did not show a
significant improvement in wear resistance. Basically, FSW is applicable mainly for butt joining of flat
plates. Therefore, FSW of cylindrical articles such as a flange to a duct with praclical diameters rangingfrom 2-5 in. must be fully demonstrated and compared with other proven MMC joining techniques for
cylindrical articles.
14. SuBJEcT TERMS
friction stir welding, metal matrix cornposiles, silicon-carbide, functional gradient materials,wear-resistant coating, ah|rnint, na-lithium 2195, flanges, ducts, pin tool,.joining technologies
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OF REPORT OF THIS PAGE OF ABSTRACT
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